Evaluating probabilistic and data-driven inference models for fiber-coupled NV-diamond temperature sensors
At a Glance
Section titled āAt a Glanceā| Metadata | Details |
|---|---|
| Publication Date | 2025-04-15 |
| Journal | Optics Express |
| Authors | Shraddha Rajpal, Zeeshan Ahmed, Tyrus Berry |
Abstract
Section titled āAbstractāWe evaluate the impact of an inference model on uncertainties when using continuous wave optically detected magnetic resonance (ODMR) measurements to infer temperature. Our approach leverages a probabilistic feedforward inference model designed to maximize the likelihood of observed ODMR spectra through automatic differentiation. This model effectively utilizes the temperature dependence of spin Hamiltonian parameters to infer temperature from spectral features in the ODMR data. We achieve prediction uncertainty of Ā± 1 K across a temperature range of 243 K to 323 K. To benchmark our probabilistic model, we compare it with a non-parametric peak-finding technique and data-driven methodologies such as principal component regression (PCR) and a 1D convolutional neural network (CNN). We find that when validated against an out-of-sample dataset that encompasses the same temperature range as the training dataset, data-driven methods can show uncertainties that are as much as 0.67 K lower without incorporating expert-level understanding of the spectroscopic-temperature relationship. However, our results show that the probabilistic model outperforms both PCR and CNN when tasked with extrapolating beyond the temperature range used in the training set, indicating robustness and generalizability. In contrast, data-driven methods like PCR and CNN demonstrate up to ten times worse uncertainties when tasked with extrapolating outside their training data range.